CTU FEE Moodle
Nanoelectronics and Nanotechnology
B232 - Summer 23/24
This is a grouped Moodle course. It consists of several separate courses that share learning materials, assignments, tests etc. Below you can see information about the individual courses that make up this Moodle course.
Nanoelectronics and Nanotechnology - A2M34NAN
Main course
| Credits | 5 |
| Semesters | Summer |
| Completion | Assessment + Examination |
| Language of teaching | Czech |
| Extent of teaching | 2P+2C |
Annotation
The subject is oriented on the present nanotechnologies in the connection with their electronic, photonic and spintrinic applications. Quantum theory basics are used to explain the effects observed in nanostructures. Basic nanoelectronic structures are described with their possible applications. Modern computer methods and models, which are able to simulate the operation of nanoelectronic structures and which are the important tools for their design and optimalisation, are studied.
Study targets
Main target of the subject is to give an overview about nanotechnology applications in electronics and spintronics and to inform students about the last achievements in the field of electronic nanodevices
Course outlines
1. Introduction - the Way to Nanoelectronics
2. Quanatum Effects in Nanostructures
3. Quantum states and wavefunctions calculations
4. Quantum transport models
5. Simulation of Nanoelectronic Devices
6. TCAD Systems
7. Modern Epitaxy
8. Nanolitography
9. 2D Systems, Resonant Tunneling Devices, HFETs
10. 1D Systems, Nanowires
11. Quantum Dots, Single-Electron Transistors
12. Spintronic Nanodevices
13. Nanoelectronics with Superconducting Devices
14. Molecular electronics, Bottom - up Concept
2. Quanatum Effects in Nanostructures
3. Quantum states and wavefunctions calculations
4. Quantum transport models
5. Simulation of Nanoelectronic Devices
6. TCAD Systems
7. Modern Epitaxy
8. Nanolitography
9. 2D Systems, Resonant Tunneling Devices, HFETs
10. 1D Systems, Nanowires
11. Quantum Dots, Single-Electron Transistors
12. Spintronic Nanodevices
13. Nanoelectronics with Superconducting Devices
14. Molecular electronics, Bottom - up Concept
Exercises outlines
1. Seminary: Semiconductor Electronics - Basics
2. Seminary: Quantum Effects in Nanostructures
3. Seminary: Quantum Effects Applications
4. Nanodevice Simulation Tools
5. RTD Simulation..
6. Quantum Dot Simulation.
7. TCAD Systems- Semiconductor Devices Design
8. Nano FET Simulation.
9. Visit in MBE, MOVPE Laboratory
10. HEMT, HBT simulation
11. Semiconductor Laser Simulation
12. Visit in AFM, BEEM, SIMS Laboratory
13. AFM,STM Microscopy
14. Conclusions
2. Seminary: Quantum Effects in Nanostructures
3. Seminary: Quantum Effects Applications
4. Nanodevice Simulation Tools
5. RTD Simulation..
6. Quantum Dot Simulation.
7. TCAD Systems- Semiconductor Devices Design
8. Nano FET Simulation.
9. Visit in MBE, MOVPE Laboratory
10. HEMT, HBT simulation
11. Semiconductor Laser Simulation
12. Visit in AFM, BEEM, SIMS Laboratory
13. AFM,STM Microscopy
14. Conclusions
Literature
1. K. Goser, P. Glösekötter, J. Dienstuhl, Nanoelectronics and Nanosystems, Springer, 2004.
2. P. Harrison, Quantum Wells, Wires and Dots, J. Wiley & Sons, 1999.
2. P. Harrison, Quantum Wells, Wires and Dots, J. Wiley & Sons, 1999.
Requirements
Basics of quantum mechanics, basics of semiconductor physics and device electronics.
Nanoelectronics and Nanotechnology - B2M34NAN
| Credits | 5 |
| Semesters | Summer |
| Completion | Assessment + Examination |
| Language of teaching | Czech |
| Extent of teaching | 2P+2C |
Annotation
The subject is oriented on the present nanotechnologies in the connection with their electronic, photonic and spintrinic applications. Quantum theory basics are used to explain the effects observed in nanostructures. Basic nanoelectronic structures are described with their possible applications. Modern computer methods and models, which are able to simulate the operation of nanoelectronic structures and which are the important tools for their design and optimalisation, are studied.
Study targets
Main target of the subject is to give an overview about nanotechnology applications in electronics and spintronics and to inform students about the last achievements in the field of electronic nanodevices.
Course outlines
1. Introduction - the Way to Nanoelectronics
2. Quanatum Effects in Nanostructures
3. Quantum states and wavefunctions calculations
4. Quantum transport models
5. Simulation of Nanoelectronic Devices
6. TCAD Systems
7. Modern Epitaxy
8. Nanolitography
9. 2D Systems, Resonant Tunneling Devices, HFETs
10. 1D Systems, Nanowires
11. Quantum Dots, Single-Electron Transistors
12. Spintronic Nanodevices
13. Nanoelectronics with Superconducting Devices
14. Molecular electronics, Bottom - up Concept
2. Quanatum Effects in Nanostructures
3. Quantum states and wavefunctions calculations
4. Quantum transport models
5. Simulation of Nanoelectronic Devices
6. TCAD Systems
7. Modern Epitaxy
8. Nanolitography
9. 2D Systems, Resonant Tunneling Devices, HFETs
10. 1D Systems, Nanowires
11. Quantum Dots, Single-Electron Transistors
12. Spintronic Nanodevices
13. Nanoelectronics with Superconducting Devices
14. Molecular electronics, Bottom - up Concept
Exercises outlines
1. Seminary: Semiconductor Electronics - Basics
2. Seminary: Quantum Effects in Nanostructures
3. Seminary: Quantum Effects Applications
4. Nanodevice Simulation Tools
5. RTD Simulation..
6. Quantum Dot Simulation.
7. TCAD Systems- Semiconductor Devices Design
8. Nano FET Simulation.
9. Visit in MBE, MOVPE Laboratory
10. HEMT, HBT simulation
11. Semiconductor Laser Simulation
12. Visit in AFM, BEEM, SIMS Laboratory
13. AFM,STM Microscopy
14. Conclusions
2. Seminary: Quantum Effects in Nanostructures
3. Seminary: Quantum Effects Applications
4. Nanodevice Simulation Tools
5. RTD Simulation..
6. Quantum Dot Simulation.
7. TCAD Systems- Semiconductor Devices Design
8. Nano FET Simulation.
9. Visit in MBE, MOVPE Laboratory
10. HEMT, HBT simulation
11. Semiconductor Laser Simulation
12. Visit in AFM, BEEM, SIMS Laboratory
13. AFM,STM Microscopy
14. Conclusions
Literature
1. K. Goser, P. Glösekötter, J. Dienstuhl, Nanoelectronics and Nanosystems, Springer, 2004.
2. P. Harrison, Quantum Wells, Wires and Dots, J. Wiley & Sons, 1999.
2. P. Harrison, Quantum Wells, Wires and Dots, J. Wiley & Sons, 1999.
Requirements
Basics of quantum mechanics, basics of semiconductor physics and device electronics.